Your search keyword '"Mateo, C."' showing total 38 results

1. Portable Alkaline Phosphatase-Hydrogel Platform: From Enzyme Characterization to Phosphate Sensing.

Author

Alacid Y, Martínez-Tomé MJ, Esquembre R, Herrero MA, and Mateo CR

Subjects

Hydrogels pharmacology, Phosphates, Temperature, Alkaline Phosphatase metabolism, Enzymes, Immobilized

Abstract

Here, we present a study on the incorporation and characterization of the enzyme alkaline phosphatase (ALP) into a three-dimensional polymeric network through a green protocol to obtain transparent hydrogels (ALP@AETA) that can be stored at room temperature and potentially used as a disposable biosensor platform for the rapid detection of ALP inhibitors. For this purpose, different strategies for the immobilization of ALP in the hydrogel were examined and the properties of the new material, compared to the hydrogel in the absence of enzyme, were studied. The conformation and stability of the immobilized enzyme were characterized by monitoring the changes in its intrinsic fluorescence as a function of temperature, in order to study the unfolding/folding process inside the hydrogel, inherently related to the enzyme activity. The results show that the immobilized enzyme retains its activity, slightly increases its thermal stability and can be stored as a xerogel at room temperature without losing its properties. A small portion of a few millimeters of ALP@AETA xerogel was sufficient to perform enzymatic activity inhibition assays, so as a proof of concept, the device was tested as a portable optical biosensor for the detection of phosphate in water with satisfactory results. Given the good stability of the ALP@AETA xerogel and the interesting applications of ALP, not only in the environmental field but also as a therapeutic enzyme, we believe that this study could be of great use for the development of new devices for sensing and protein delivery.

Published

2023

2. Multi-Point Covalent Immobilization of Enzymes on Glyoxyl Agarose with Minimal Physico-Chemical Modification: Stabilization of Industrial Enzymes.

Author

López-Gallego F, Fernandez-Lorente G, Rocha-Martín J, Bolivar JM, Mateo C, and Guisan JM

Subjects

Biotechnology, Enzyme Activation, Enzyme Stability, Hydrogen-Ion Concentration, Oxidation-Reduction, Chemical Engineering, Chemical Phenomena, Enzymes, Immobilized chemistry, Glyoxylates chemistry, Sepharose chemistry

Abstract

Stabilization of enzymes via immobilization techniques is a valuable approach in order to convert a necessary protocol (immobilization) into a very interesting tool to improve key enzyme properties (stabilization). Multipoint covalent attachment of each immobilized enzyme molecule may promote a very interesting stabilizing effect. The relative distances among all enzyme residues involved in immobilization have to remain unaltered during any conformational change induced by any distorting agent. Amino groups are very interesting nucleophiles placed on protein surfaces. The immobilization of enzyme through the region having the highest amount of amino groups (Lys residues) is key for a successful stabilization. Glyoxyl groups are small aliphatic aldehydes that form very unstable Schiff's bases with amino groups, and they do not seem to be useful for enzyme immobilization at neutral pH. However, under alkaline conditions, glyoxyl supports are able to immobilize enzymes via a first multipoint covalent immobilization through the region having the highest amount of lysine groups. Activation of supports with a high surface density of glyoxyl groups and the performance of very intense enzyme-support multipoint covalent attachments are here described.

Published

2020

3. Multi-Point Covalent Immobilization of Enzymes on Supports Activated with Epoxy Groups: Stabilization of Industrial Enzymes.

Author

Mateo C, Abian O, Fernandez-Lorente G, Pessela BCC, Grazu V, Guisan JM, and Fernandez-Lafuente R

Subjects

Adsorption, Enzyme Activation, Enzyme Stability, Epoxy Resins, Hydrogen-Ion Concentration, Hydrophobic and Hydrophilic Interactions, Protein Binding, Proteins chemistry, Thermodynamics, Enzymes, Immobilized chemistry, Epoxy Compounds chemistry

Abstract

Commercial epoxy supports may be very useful tools to stabilize proteins via multipoint covalent attachment if the immobilization is properly designed. In this chapter, a protocol to take full advantage of the support's possibilities is described. The basics of the protocol are as follows: (1) the enzymes are hydrophobically adsorbed on the supports at high ionic strength. (2) There is an "intermolecular" covalent reaction between the adsorbed protein and the supports. (3) The immobilized protein is incubated at alkaline pH to increase the multipoint covalent attachment, thereby stabilizing the enzyme. (4) The hydrophobic surface of the support is hydrophylized by reaction of the remaining groups with amino acids in order to reduce the unfavorable enzyme-support hydrophobic interactions. This strategy has produced a significant increase in the stability of penicillin G acylase compared with the stability achieved using conventional protocols.

Published

2020

4. Very Strong but Reversible Immobilization of Enzymes on Supports Coated with Ionic Polymers.

Author

Mateo C, Pessela BCC, Fuentes M, Torres R, Ortiz C, López-Gallego F, Betancor L, Alonso-Morales N, Guisan JM, and Fernandez-Lafuente R

Subjects

Adsorption, Cation Exchange Resins, Chemical Phenomena, Enzyme Activation, Enzyme Stability, Hydrogen-Ion Concentration, Osmolar Concentration, Polyethyleneimine chemistry, Solvents, Temperature, Enzymes, Immobilized chemistry, Ions chemistry, Polymers chemistry

Abstract

In this chapter, the properties of tailor-made anionic exchanger resins based on films of large polyethylenimine polymers (e.g., molecular weight 25,000) as supports for strong but reversible immobilization of proteins are shown. The polymer is completely coated, via covalent immobilization, the surface of different porous supports. Proteins can interact with this polymeric bed, involving a large percentage of the protein surface in the adsorption. Different enzymes have been very strongly adsorbed on these supports, retaining enzyme activities. On the other hand, adsorption is very strong and the derivatives may be used under a wide range of pH and ionic strengths. These supports may be useful even to stabilize multimeric enzymes, by involving several enzyme subunits in the immobilization.

Published

2020

5. Stabilization of Multimeric Enzymes via Immobilization and Further Cross-Linking with Aldehyde-Dextran.

Author

Mateo C, Pessela BCC, Fuentes M, Torres R, Betancor L, Hidalgo A, Fernandez-Lorente G, Fernandez-Lafuente R, and Guisan JM

Subjects

Acetobacter enzymology, Enzyme Activation, Enzyme Stability, Molecular Structure, Protein Conformation, Protein Multimerization, Proteins chemistry, Thermodynamics, Aldehydes chemistry, Cross-Linking Reagents chemistry, Dextrans chemistry, Enzymes, Immobilized chemistry

Abstract

Subunit dissociation of multimeric proteins is one of the most important causes of inactivation of proteins having quaternary structure, making these proteins very unstable under diluted conditions. A sequential two-step protocol for the stabilization of this protein is proposed. A multisubunit covalent immobilization may be achieved by performing very long immobilization processes between multimeric enzymes and porous supports composed of large internal surfaces and covered by a very dense layer of reactive groups. Additional cross-linking with polyfunctional macromolecules promotes the complete cross-linking of the subunits to fully prevent enzyme dissociation. Full stabilization of multimeric structures has been physically shown because no subunits were desorbed from derivatives after boiling them in SDS. As a functional improvement, these immobilized preparations no longer depend on the enzyme.

Published

2020

6. New Heterofunctional Supports Based on Glutaraldehyde-Activation: A Tool for Enzyme Immobilization at Neutral pH.

Author

Melo RR, Alnoch RC, Vilela AFL, Souza EM, Krieger N, Ruller R, Sato HH, and Mateo C

Subjects

Candida chemistry, Candida enzymology, Enzyme Activation, Enzyme Stability, Enzymes, Immobilized isolation & purification, Escherichia coli chemistry, Escherichia coli enzymology, Escherichia coli Proteins chemistry, Fungal Proteins chemistry, Hydrophobic and Hydrophilic Interactions, beta-Galactosidase isolation & purification, Enzymes, Immobilized chemistry, Glutaral chemistry, beta-Galactosidase chemistry

Abstract

Immobilization is an exciting alternative to improve the stability of enzymatic processes. However, part of the applied covalent strategies for immobilization uses specific conditions, generally alkaline pH, where some enzymes are not stable. Here, a new generation of heterofunctional supports with application at neutral pH conditions was proposed. New supports were developed with different bifunctional groups (i.e., hydrophobic or carboxylic/metal) capable of adsorbing biocatalysts at different regions (hydrophobic or histidine richest place), together with a glutaraldehyde group that promotes an irreversible immobilization at neutral conditions. To verify these supports, a multi-protein model system ( E. coli extract) and four enzymes ( Candida rugosa lipase, metagenomic lipase, β-galactosidase and β-glucosidase) were used. The immobilization mechanism was tested and indicated that moderate ionic strength should be applied to avoid possible unspecific adsorption. The use of different supports allowed the immobilization of most of the proteins contained in a crude protein extract. In addition, different supports yielded catalysts of the tested enzymes with different catalytic properties. At neutral pH, the new supports were able to adsorb and covalently immobilize the four enzymes tested with different recovered activity values. Notably, the use of these supports proved to be an efficient alternative tool for enzyme immobilization at neutral pH., Competing Interests: The authors declare no conflict of interest.

Published

2017

7. Immobilization of enzymes on monofunctional and heterofunctional epoxy-activated supports.

Author

Mateo C, Grazu V, and Guisan JM

Subjects

Adsorption, Enzyme Stability, Escherichia coli Proteins chemistry, Fungal Proteins chemistry, Hydrogen-Ion Concentration, Ion Exchange, Penicillin Amidase chemistry, Polymers chemistry, beta-Galactosidase chemistry, Cross-Linking Reagents chemistry, Enzymes, Immobilized chemistry, Epoxy Compounds chemistry

Abstract

The immobilization of proteins on epoxy activated supports is discussed in this chapter. Immobilization on epoxy supports is carried out as a two-step mechanism: in the first step the adsorption of the protein is promoted and in the second step the intramolecular covalent linkage among epoxy groups and nucleophiles of the protein is produced. Based on this mechanism of the need of a first adsorption of the protein on the support, different epoxy supports are described. The different supports are able to immobilize proteins through different orientations being obtained catalysts with different properties of activity, stability, and selectivity.

Published

2013

8. Oriented covalent immobilization of enzymes on heterofunctional-glyoxyl supports.

Author

Mateo C, Fernandez-Lorente G, Rocha-Martin J, Bolivar JM, and Guisan JM

Subjects

Adsorption, Animals, Bacterial Proteins chemistry, Carboxylic Ester Hydrolases chemistry, Chymotrypsin chemistry, Enzyme Assays, Enzyme Stability, Hydrogen-Ion Concentration, Lipase chemistry, Stereoisomerism, Substrate Specificity, Cross-Linking Reagents chemistry, Enzymes, Immobilized chemistry, Glyoxylates chemistry, Sepharose chemistry

Abstract

Novel heterofunctional glyoxyl-agarose supports were prepared. These supports contained the maximal concentration of glyoxyl groups to promote maximization of covalent immobilization and groups' capability to adsorb proteins by various mechanisms (e.g., ionic exchange, metal-chelate formation). Immobilization on various supports makes it possible to orientate and rigidify an enzyme in various regions of its surface. The use of different heterofunctional supports allowed for obtaining catalysts with different activity, stability, and selectivity properties.

Published

2013

9. Stabilization of enzymes by multipoint covalent immobilization on supports activated with glyoxyl groups.

Author

López-Gallego F, Fernandez-Lorente G, Rocha-Martin J, Bolivar JM, Mateo C, and Guisan JM

Subjects

Amines chemistry, Cross-Linking Reagents chemistry, Enzyme Stability, Hydrogen-Ion Concentration, Lysine chemistry, Protein Binding, Schiff Bases chemistry, Enzymes, Immobilized chemistry, Escherichia coli Proteins chemistry, Glyoxylates chemistry, Penicillin Amidase chemistry, Sepharose chemistry

Abstract

Stabilization of enzymes via immobilization techniques is a valuable approach in order to convert a necessary protocol (immobilization) into a very interesting tool to improve key enzyme properties (stabilization). Multipoint covalent attachment of each immobilized enzyme molecule may promote a very interesting stabilizing effect. The relative distances among all enzyme residues involved in immobilization has to remain unaltered during any conformational change induced by any distorting agent. Amino groups are very interesting nucleophiles placed on protein surfaces. The immobilization of enzyme through the region having the highest amount of amino groups (Lys residues) is key for a successful stabilization. Glyoxyl groups are small aliphatic aldehydes that form very unstable Schiff's bases with amino groups and they do not seem to be useful for enzyme immobilization at neutral pH. However, under alkaline conditions, glyoxyl supports are able to immobilize enzymes via a first multipoint covalent immobilization through the region having the highest amount of Lysine groups. Activation of supports with a high surface density of glyoxyl groups and the performance of very intense enzyme-support multipoint covalent attachments are here described.

Published

2013

10. Full enzymatic hydrolysis of commercial sucrose laurate by immobilized-stabilized derivatives of lipase from Thermomyces lanuginosa.

Author

Marciello M, Mateo C, and Guisan JM

Subjects

Hydrolysis, Sucrose chemistry, Time Factors, Ascomycota enzymology, Enzymes, Immobilized chemistry, Lipase chemistry, Sucrose analogs & derivatives

Abstract

Sucrose laurate is a detergent that is useful for various biochemical applications because it is a green compound and is easily degradable after hydrolysis with a lipase or esterase. One problem observed in the process of sucrose laurate degradation is that most commercial detergent preparations are impure, necessitating the hydrolysis of all of the sucrose esters present in the preparation, all of them with detergent properties. In this article, a highly active catalyst, which is able to perform the hydrolysis of commercial sucrose laurate, is presented. The use of glyoxyl agarose preparations of a previously aminated Thermomyces lanuginosa lipase (TLL) enabled complete hydrolysis, in less than 30 min, of all of the compounds that comprise the mixture. In addition, this derivative is stable in the presence of 20% ethanol, which is necessary to prevent microbial contamination., (Copyright © 2011 Elsevier B.V. All rights reserved.)

Published

2011

11. Purification, immobilization, and characterization of a specific lipase from Staphylococcus warneri EX17 by enzyme fractionating via adsorption on different hydrophobic supports.

Author

Volpato G, Filice M, de las Rivas B, Rodrigues RC, Heck JX, Fernandez-Lafuente R, Guisan JM, Mateo C, and Ayub MA

Subjects

Adsorption, Detergents chemistry, Hydrophobic and Hydrophilic Interactions, Lipase chemistry, Lipase metabolism, Chromatography methods, Enzymes, Immobilized isolation & purification, Lipase isolation & purification, Staphylococcus enzymology

Abstract

Staphylococcus warneri strain EX17 produces three lipases with different molecular weights of 28, 30, and 45 kDa. The 45 kDa fraction (SWL-45) has been purified from crude protein extracts by one chromatographic step based on the selective adsorption of this lipase by interfacial activation on different hydrophobic supports at low ionic strength. The adsorption of SWL-45 on octyl-Sepharose increased the enzyme activity by 60%, but the other lipases were also adsorbed on this support. Using butyl-Toyopearl, which is a lesser hydrophobic support, the purification factor was close to 20, and the only protein band detected on the sodium dodecyl sulfate-polyacrylamide electrophoresis analysis gel was that corresponding to the SWL-45, which could be easily desorbed from the support by incubation with triton X-100, producing a purified enzyme. SWL-45 was immobilized under very mild conditions on cyanogen bromide Sepharose, showing similar activities and stability as for its soluble form but without intermolecular interaction. The effects of different detergents over the activity of the immobilized SWL-45 were analyzed, which was hyperactivated by factors of 1.3 and 2.5 with 0.01% Tween 80 and 0.1% Triton X-100, respectively, while ionic detergents produced detrimental effects on the enzyme activity even at very low concentrations. Optimal reaction conditions and the effect of other additives on the enzyme activity were also investigated., (Copyright © 2011 American Institute of Chemical Engineers (AIChE).)

Published

2011

12. Improvement of enzyme properties with a two-step immobilizaton process on novel heterofunctional supports.

Author

Mateo C, Bolivar JM, Godoy CA, Rocha-Martin J, Pessela BC, Curiel JA, Muñoz R, Guisan JM, and Fernández-Lorente G

Subjects

Adsorption, Animals, Carboxylic Ester Hydrolases chemistry, Chymotrypsin chemistry, Enzyme Stability, Geobacillus enzymology, Hydrogen-Ion Concentration, Lactobacillus plantarum enzymology, Lipase chemistry, Pancreas enzymology, Surface Properties, Swine, Carboxylic Ester Hydrolases metabolism, Chymotrypsin metabolism, Enzymes, Immobilized chemistry, Enzymes, Immobilized metabolism, Glyoxylates chemistry, Lipase metabolism, Sepharose chemistry

Abstract

Novel heterofunctional glyoxyl-agarose supports were prepared. These supports contain a high concentration of groups (such as quaternary ammonium groups, carboxyl groups, and metal chelates) that are capable of adsorbing proteins, physically or chemically, at neutral pH as well as a high concentration of glyoxyl groups that are unable to immobilize covalently proteins at neutral pH. By using these supports, a two-step immobilization protocol was developed. In the first step, enzymes were adsorbed at pH 7.0 through adsorption of surface regions, which are complementary to the adsorbing groups on the support, and in the second step, the immobilized derivatives were incubated under alkaline conditions to promote an intramolecular multipoint covalent attachment between the glyoxyl groups on the support and the amino groups on the enzyme surface. These new derivatives were compared with those obtained on a monofunctional glyoxyl support at pH 10, in which the region with the greatest number of lysine residues participates in the first immobilization step. In some cases, multipoint immobilization on heterofunctional supports was much more efficient than what was achieved on the monofunctional support. For example, derivatives of tannase from Lactobacillus plantarum on an amino-glyoxyl heterofunctional support were 20-fold more stable than the best derivative on a monofunctional glyoxyl support. Derivatives of lipase from Geobacillus thermocatenulatus (BTL2) on the amino-glyoxyl supports were two times more active and four times more enantioselective than the corresponding monofunctional glyoxyl support derivative.

Published

2010

13. Multienzymatic system immobilization in sol-gel slides: fluorescent superoxide biosensors development.

Author

Pastor I, Salinas-Castillo A, Esquembre R, Mallavia R, and Mateo CR

Subjects

Antioxidants chemistry, Equipment Design, Equipment Failure Analysis, Phase Transition, Reproducibility of Results, Sensitivity and Specificity, Antioxidants analysis, Biosensing Techniques instrumentation, Enzymes, Immobilized chemistry, Multienzyme Complexes chemistry, Spectrometry, Fluorescence instrumentation, Superoxides chemistry

Abstract

One of the potential areas of research in the development of biosensors is the production of analytical devices based on the use of immobilized multienzymatic systems. In this work, we report the development of three analytical systems for superoxide radical detection using sol-gel technology to immobilize enzyme systems. These systems are based on the connected reactions of three enzymes (xanthine oxidase, superoxide dismutase and horseradish peroxidase) coupled to the probe Amplex red. The difference between these three systems lies in the immobilization of two or three enzymes into a single or in different sol-gel slides. We check the potential use of each designed systems to quantify superoxide radical and potential evaluation of radical scavenging properties of several antioxidant compounds., (Copyright 2009 Elsevier B.V. All rights reserved.)

Published

2010

14. Coating of soluble and immobilized enzymes with ionic polymers: full stabilization of the quaternary structure of multimeric enzymes.

Author

Bolivar JM, Rocha-Martin J, Mateo C, Cava F, Berenguer J, Fernandez-Lafuente R, and Guisan JM

Subjects

Cation Exchange Resins metabolism, Coated Materials, Biocompatible, Enzyme Stability, Enzymes, Immobilized metabolism, Formate Dehydrogenases metabolism, Glutamate Dehydrogenase metabolism, Glutaral metabolism, Pseudomonas enzymology, Sodium Chloride metabolism, Thermus thermophilus enzymology, Enzymes, Immobilized chemistry, Formate Dehydrogenases chemistry, Glutamate Dehydrogenase chemistry, Polyethyleneimine chemistry, Polymers chemistry, Protein Structure, Quaternary

Abstract

This paper shows a simple and effective way to avoid the dissociation of multimeric enzymes by coating their surface with a large cationic polymer (e.g., polyethylenimine (PEI)) by ionic exchange. As model enzymes, glutamate dehydrogenase (GDH) from Thermus thermophilus and formate dehydrogenase (FDH) from Pseudomonas sp. were used. Both enzymes are very unstable at acidic pH values due to the rapid dissociation of their subunits (half-life of diluted preparations is few minutes at pH 4 and 25 degrees C). GDH and FDH were incubated in the presence of PEI yielding an enzyme-PEI composite with full activity. To stabilize the enzyme-polymer composite, a treatment with glutaraldehyde was required. These enzyme-PEI composites can be crosslinked with glutaraldehyde by immobilizing previously the composite onto a weak cationic exchanger. The soluble GDH-PEI composite was much more stable than unmodified GDH at pH 4 and 30 degrees C (retaining over 90% activity after 24 h incubation) with no effect of the GDH concentration in the inactivation course. The composite could be very strongly, but reversibly, adsorbed on cationic exchangers. Similarly, FDH could be treated with PEI and glutaraldehyde after adsorption on cationic exchangers, This permitted a stabilized FDH preparation. In this way, the coating of the enzymes surfaces with PEI is used as a simple and efficient strategy to prevent enzyme dissociation of multimeric enzymes. These composites can be used as a soluble catalyst or reversibly immobilized onto a cationic exchanger (e.g., CM-agarose).

Published

2009

15. Advances in the design of new epoxy supports for enzyme immobilization-stabilization.

Author

Mateo C, Grazú V, Pessela BC, Montes T, Palomo JM, Torres R, López-Gallego F, Fernández-Lafuente R, and Guisán JM

Subjects

Binding Sites, Enzyme Stability, Enzymes, Immobilized chemistry, Epoxy Compounds chemistry

Abstract

Multipoint covalent immobilization of enzymes (through very short spacer arms) on support surfaces promotes a very interesting 'rigidification' of protein molecules. In this case, the relative positions of each residue of the enzyme involved in the immobilization process have to be preserved unchanged during any conformational change induced on the immobilized enzyme by any distorting agent (heat, organic solvents etc.). In this way, multipoint covalent immobilization should induce a very strong stabilization of immobilized enzymes. Epoxy-activated supports are able to chemically react with all nucleophile groups placed on the protein surface: lysine, histidine, cysteine, tyrosine etc. Besides, epoxy groups are very stable. This allows the performance of very long enzyme-support reactions, enabling us to get very intense multipoint covalent attachment. In this way, these epoxy supports seem to be very suitable to stabilize industrial enzymes by multipoint covalent attachment. However, epoxy groups exhibit a low intermolecular reactivity towards nucleophiles and hence the enzymes are not able to directly react with the epoxy supports. Thus a rapid physical adsorption of enzymes on the supports becomes a first step, followed by an additional rapid 'intramolecular' reaction between the already adsorbed enzyme and the activated support. In this situation, a suitable first orientation of the enzyme on the support (e.g. through regions that are very rich in nucleophiles) is obviously necessary to get a very intense additional multipoint covalent immobilization. The preparation of different 'generations' of epoxy supports and the design of different protocols to fully control the first interaction between enzymes and epoxy supports will be reviewed in this paper. Finally, the possibilities of a directed immobilization of mutated enzymes (change of an amino acid by cysteine on specific points of the protein surface) on tailor-made disulfide-epoxy supports will be discussed as an almost-ideal procedure to achieve very intense and very efficient rigidification of a desired region of industrial enzymes.

Published

2007

16. Partial purification and immobilization/stabilization on highly activated glyoxyl-agarose supports of different proteases from flavourzyme.

Author

Yust Mdel M, Pedroche J, Alaiz M, Girón-Calle J, Vioque J, Mateo C, Guisan JM, Millan F, and Fernandez-Lafuente R

Subjects

Adsorption, Cicer chemistry, Endopeptidases chemistry, Enzyme Stability, Hydrolysis, Plant Proteins metabolism, Protein Hydrolysates, Endopeptidases isolation & purification, Endopeptidases metabolism, Enzymes, Immobilized, Glyoxylates, Sepharose

Abstract

The fractioning of some components and their immobilization of Flavourzyme, a commercial protease/aminopeptidase preparation, has been investigated to improve its specificity and stability. Adsorption of Flavourzyme on two ionic exchangers yielded two fractions with endoprotease activity and one fraction containing aminopeptidase activity. The use of an amine agarose gel has made it possible to purify a 43 kDa protein with only endoprotease activity. Immobilization of this endoprotease and the original Flavourzyme preparation onto glyoxyl-agarose provided derivatives that were more thermostable than their soluble counterparts. Tests using immobilized Flavourzyme and immobilized purified endoprotease for the hydrolysis of chickpea proteins showed that both preparations can be used for the production of protein hydrolysates and compare very favorably with the original crude Flavourzyme in terms of reducing the production of free amino acids. This was especially so in the case of immobilized endoprotease, which produced only 0.2% free amino acids. Keeping free amino acids content low is very important in protein hydrolysates for nutritional use to avoid excessive osmotic pressure.

Published

2007

17. Immobilization of enzymes on heterofunctional epoxy supports.

Author

Mateo C, Grazu V, Palomo JM, Lopez-Gallego F, Fernandez-Lafuente R, and Guisan JM

Subjects

Bioreactors, Biotechnology methods, Enzymes, Immobilized chemistry, Epoxy Compounds chemistry, Proteins chemistry

Abstract

Immobilization of enzymes and proteins on activated supports permits the simplification of the reactor design and may be used to improve some enzyme properties. In this sense, supports containing epoxy groups seem to be useful to generate very intense multipoint covalent attachment with different nucleophiles placed on the surface of enzyme molecules (e.g., amino, thiol, hydroxyl groups). However, the intermolecular reaction between epoxy groups and soluble enzymes is extremely slow. To solve this problem, we have designed "tailor-made" heterofunctional epoxy supports. Using these, immobilization of enzymes is performed via a two-step process: (i) an initial physical or chemical intermolecular interaction of the enzyme surface with the new functional groups introduced on the support surface and (ii) a subsequent intense intramolecular multipoint covalent reaction between the nucleophiles of the already immobilized enzyme and the epoxy groups of the supports. The first immobilization may involve different enzyme regions, which will be further rigidified by multipoint covalent attachment. The design of some heterofunctional epoxy supports and the performance of the immobilization protocols are described here. The whole protocol to have an immobilized and stabilized enzyme could take from 3 days to 1 week.

Published

2007

18. Glutaraldehyde cross-linking of lipases adsorbed on aminated supports in the presence of detergents leads to improved performance.

Author

Fernández-Lorente G, Palomo JM, Mateo C, Munilla R, Ortiz C, Cabrera Z, Guisán JM, and Fernandez-Lafuente R

Subjects

Adsorption, Biochemistry methods, Candida enzymology, Enzyme Stability, Hydrolysis, Models, Chemical, Sepharose chemistry, Spectrophotometry, Biocompatible Materials chemistry, Biotechnology methods, Cross-Linking Reagents chemistry, Detergents pharmacology, Enzymes, Immobilized chemistry, Glutaral chemistry, Lipase chemistry

Abstract

Lipases from Candida rugosa (CRL) and lipase isoforms A and B from Candida antarctica (CAL-A and CAL-B) were adsorbed on aminated supports in the presence of detergents to have individual lipase molecules. Then, one fraction was washed to eliminate the detergent, and both preparations were treated with glutaraldehyde. The presence of detergent during the cross-linking of the lipases to the support permitted an increase in the recovered activity (in some instances, even by a 10-fold factor). This activity was higher even than that exhibited by the just adsorbed lipases, suggesting that it was not a result of some protective effect of the detergent in the enzyme activity during glutaraldehyde chemical modification. Moreover, the enantioselectivity of the different enzyme preparations was very different if the glutaraldehyde was offered in the presence or in the absence of detergent, in some cases increasing the E value (even by a 7-fold factor in the case of CAL-A in the hydrolysis of (+/-)-2-hydroxy-4-phenylbutyric acid ethyl ester), in other cases even inverting the enantio preference (e.g., in the case of CRL). The irreversible chemical inhibition of the enzyme that was immobilized and cross-linked with glutaraldehyde in the presence of detergents was more rapid than that in the other preparations (by more than a 10-fold factor). This experiment reveals an exposition degree of the active serine in the preparation cross-linked with the support in the presence of detergent that is higher than that in the other preparations. The results suggested that different enzyme structures were "stabilized" by the glutaraldehyde treatment if performed in the presence or in the absence of detergent, and that, in the presence of detergent, a form of the lipase with the serine residue more exposed to the medium and much more active could be obtained. This strategy seems to be of general use to improve the lipase activity to be used in macroaqueous media.

Published

2006

19. Improvement of the stability of alcohol dehydrogenase by covalent immobilization on glyoxyl-agarose.

Author

Bolivar JM, Wilson L, Ferrarotti SA, Guisán JM, Fernández-Lafuente R, and Mateo C

Subjects

Alcohol Dehydrogenase chemistry, Animals, Enzyme Stability drug effects, Enzymes, Immobilized chemistry, Glyoxylates pharmacology, Horses, Hydrogen-Ion Concentration, Liver enzymology, Protein Structure, Tertiary drug effects, Sepharose pharmacology, Solvents chemistry, Solvents pharmacology, Temperature, Time Factors, Alcohol Dehydrogenase metabolism, Enzymes, Immobilized metabolism, Glyoxylates chemistry, Sepharose chemistry

Abstract

Immobilization of alcohol dehydrogenase (ADH) from Horse Liver inside porous supports promotes a dramatic stabilization of the enzyme against inactivation by air bubbles in stirred tank reactors. Moreover, immobilization of ADH on glyoxyl-agarose promotes additional stabilization against any distorting agent (pH, temperature, organic solvents, etc.). Stabilization is higher when using highly activated supports, they are able to immobilize both subunits of the enzyme. The best glyoxyl derivatives are much more stable than conventional ADH derivatives (e.g., immobilized on BrCN activated agarose). For example, glyoxyl immobilized ADH preserved full activity after incubation at pH 5.0 for 20h at room temperature and conventional derivatives (as well as the soluble enzyme) preserved less than 50% of activity after incubation under the same conditions. Moreover, glyoxyl derivatives are more than 10 times more stable than BrCN derivatives when incubated in 50% acetone at pH 7.0. Multipoint covalent immobilization, in addition to multisubunit immobilization, seems to play an important stabilizing role against distorting agents. In spite of these interesting stabilization factors, immobilization hardly promotes losses of catalytic activity (keeping values near to 90%). This immobilized preparation is able to keep good activity using dextran-NAD(+). In this way, ADH glyoxyl immobilized preparation seems to be suitable to be used as cofactor-recycling enzyme-system in interesting NAD(+)-mediated oxidation processes, catalyzed by other immobilized dehydrogenases in stirred tank reactors.

Published

2006

20. Immobilization and stabilization of a cyclodextrin glycosyltransferase by covalent attachment on highly activated glyoxyl-agarose supports.

Author

Ferrarotti SA, Bolivar JM, Mateo C, Wilson L, Guisan JM, and Fernandez-Lafuente R

Subjects

Ethanol chemistry, Hydrogen-Ion Concentration, Temperature, Time Factors, Enzymes, Immobilized chemistry, Glucosyltransferases chemistry, Glyoxylates chemistry, Sepharose chemistry

Abstract

Covalent immobilization of cyclodextrin glycosyltransferase on glyoxyl-agarose beads promotes a very high stabilization of the enzyme against any distorting agent (temperature, pH, organic solvents). For example, the optimized immobilized preparation preserves 90% of initial activity when incubated for 22 h in 30% ethanol at pH 7 and 40 degrees C. Other immobilized preparations (obtained via other immobilization protocols) exhibit less than 10% of activity after incubation under similar conditions. Optimized glyoxyl-agarose immobilized preparation expressed a high percentage of catalytic activity (70%). Immobilization using any technique prevents enzyme inactivation by air bubbles during strong stirring of the enzyme. Stabilization of the enzyme immobilized on glyoxyl-agarose is higher when using the highest activation degree (75 micromol of glyoxyl per milliliter of support) as well as when performing long enzyme-support incubation times (4 h) at room temperature. Multipoint covalent immobilization seems to be responsible for this very high stabilization associated to the immobilization process on highly activated glyoxyl-agarose. The stabilization of the enzyme against the inactivation by ethanol seems to be interesting to improve cyclodextrin production: ethanol strongly inhibits the enzymatic degradation of cyclodextrin while hardly affecting the cyclodextrin production rate of the immobilized-stabilized preparation.

Published

2006

21. Stabilization of a formate dehydrogenase by covalent immobilization on highly activated glyoxyl-agarose supports.

Author

Bolivar JM, Wilson L, Ferrarotti SA, Fernandez-Lafuente R, Guisan JM, and Mateo C

Subjects

Biocompatible Materials chemistry, Catalysis, Dextrans chemistry, Hydrogen-Ion Concentration, Macromolecular Substances chemistry, NAD chemistry, Protein Structure, Quaternary, Pseudomonas enzymology, Solvents chemistry, Temperature, Enzymes, Immobilized chemistry, Formate Dehydrogenases chemistry, Glyoxylates chemistry, Sepharose chemistry

Abstract

Formate dehydrogenase (FDH) is a stable enzyme that may be readily inactivated by the interaction with hydrophobic interfaces (e.g., due to strong stirring). This may be avoided by immobilizing the enzyme on a porous support by any technique. Thus, even if the enzyme is going to be used in an ultra-membrane reactor, the immobilization presents some advantages. Immobilization on supports activated with bromocianogen, polyethylenimine, glutaraldehyde, etc., did not promote any stabilization of the enzyme under thermal inactivation. However, the immobilization of FDH on highly activated glyoxyl agarose has permitted increasing the enzyme stability against any distorting agent: pH, T, organic solvent, etc. The time of support-enzyme reaction, the temperature of immobilization, and the activation of the support need to be optimized to get the optimal stability-activity properties. Optimized biocatalyst retained 50% of the offered activity and became 50 times more stable at high temperature and neutral pH. Moreover, the quaternary structure of this dimeric enzyme becomes stabilized by immobilization under optimized conditions. Thus, at acidic pH (conditions where the subunit dissociation is the first step in the enzyme inactivation), the immobilization of both subunits of the enzyme on glyoxyl-agarose has allowed the enzyme to be stabilized by hundreds of times. Moreover, the optimal temperature of the enzyme has been increased (even by 10 degrees C at pH 4.5). Very interestingly, the activity with NAD(+)-dextran was around 60% of that observed with free cofactor.

Published

2006

22. Detection of polyclonal antibody against any area of the protein-antigen using immobilized protein-antigens: the critical role of the immobilization protocol.

Author

Fuentes M, Mateo C, Fernández-Lafuente R, and Guisán JM

Subjects

Adsorption, Aldehydes chemistry, Antigen-Antibody Reactions, Dextrans chemistry, Enzyme Stability, Enzymes, Immobilized immunology, Horseradish Peroxidase immunology, Sepharose chemistry, Surface Properties, Time Factors, Antibodies chemistry, Antigens chemistry, Enzymes, Immobilized chemistry, Horseradish Peroxidase chemistry

Abstract

Antigens immobilized on solid supports may be used to detect or purify their corresponding antibodies (Ab) from serum. Direct immobilization of antigens on support surfaces (through short spacer arms) may promote interesting stabilizing effects on the immobilized antigen. However, the proximity of the support may prevent the interaction of some fractions of polyclonal Ab with some regions of the antigen (those placed in close contact with the support surface). Horseradish peroxidase (HRP) was immobilized on agarose by different protocols of multipoint covalent immobilization involving different regions of the antigen surface. Glyoxyl-agarose, BrCN-agarose, and glutaraldehyde-agarose were used as activated supports. Each HRP-immobilized preparation was much more stable than the soluble enzyme, but it was only able to adsorb up to 60-70% of a mixture of polyclonal anti-HRP antibodies. On the other hand, HRP was also immobilized on agarose through a very long, flexible, and hydrophilic spacer arm (dextran). This immobilized HRP was hardly stabilized, but it was able to adsorb 100% of the polyclonal anti-HRP. The absence of steric hindrances seems to play a critical role favoring the complete recognition of all classes of polyclonal Ab. Another solution to achieve a complete adsorption of polyclonal Ab on immobilized-stabilized antigens has been also reached by using a mixture of the differently immobilized and stabilized HRP-agarose preparations. In this case, an improved storage and operational stabilities of the immobilized antigens can be combined with the complete adsorption of any class of antibody.

Published

2006

23. Enzyme stabilization by glutaraldehyde crosslinking of adsorbed proteins on aminated supports.

Author

López-Gallego F, Betancor L, Mateo C, Hidalgo A, Alonso-Morales N, Dellamora-Ortiz G, Guisán JM, and Fernández-Lafuente R

Subjects

Adsorption, Cross-Linking Reagents chemistry, D-Amino-Acid Oxidase chemistry, Enzyme Stability, Glucose Oxidase chemistry, Penicillin Amidase chemistry, Biotechnology methods, Enzymes, Immobilized chemistry, Glutaral chemistry

Abstract

The stabilization achieved by different immobilization protocols have been compared using three different enzymes (glutaryl acylase (GAC), D-aminoacid oxidase (DAAO), and glucose oxidase (GOX)): adsorption on aminated supports, treatment of this adsorbed enzymes with glutaraldehyde, and immobilization on glutaraldehyde pre-activated supports. In all cases, the treatment of adsorbed enzymes on amino-supports with glutaraldehyde yielded the higher stabilizations: in the case of GOX, a stabilization over 400-fold was achieved. After this treatment, the enzymes could no longer be desorbed from the supports using high ionic strength (suggesting the support-protein reaction). Modification of the enzymes immobilized on supports that did not offer the possibility of react with glutaraldehyde showed the same stability that the non modified preparations demonstrating that the mere chemical modification did not have effect on the enzyme stability. This simple strategy seems to permit very good results in terms of immobilization rate and stability, offering some advantages when compared to the immobilization on glutaraldehyde pre-activated supports.

Published

2005

24. A ready-to-use fluorimetric biosensor for superoxide radical using superoxide dismutase and peroxidase immobilized in sol-gel glasses.

Author

Pastor I, Esquembre R, Micol V, Mallavia R, and Mateo CR

Subjects

Anions chemistry, Calibration, Dimyristoylphosphatidylcholine analysis, Dimyristoylphosphatidylcholine chemistry, Fluorescent Dyes chemistry, Fluorometry instrumentation, Gels chemistry, Glass, Kinetics, Liposomes chemistry, Molecular Structure, Oxazines chemistry, Oxidation-Reduction, Sensitivity and Specificity, Solutions chemistry, Spectrum Analysis, Xanthine, Biosensing Techniques instrumentation, Biosensing Techniques methods, Enzymes, Immobilized metabolism, Fluorometry methods, Horseradish Peroxidase metabolism, Superoxide Dismutase metabolism, Superoxides analysis

Abstract

In this work, a highly sensitive fluorescent biosensor for quantitative superoxide radical detection, based on the coupled reaction superoxide dismutase-peroxidase enzymes and the use of the probe Amplex red, is described. Superoxide anion radical was produced via oxidation of xanthine by xanthine oxidase. Dismutation of superoxide was catalyzed by superoxide dismutase, generating hydrogen peroxide, which reacted stoichiometrically with the nonfluorescent Amplex red, in the presence of peroxidase, yielding the red-fluorescent oxidation product resorufin. The coupled superoxide dismutase-peroxidase system was immobilized in a single sol-gel matrix. The enzymatic activity of the encapsulated superoxide dismutase-peroxidase system was nearly identical to that of one of the soluble enzymes, indicating that sol-gel encapsulation preserved the hierarchy of the enzyme's activity. Specificity and reusability of the encapsulated system for up to four cycles were also demonstrated. The fluorescent biosensor was able to detect concentrations of superoxide as low as 20 nM in phospholipid model membranes composed of saturated or unsaturated phospholipids. These facts make this biosensor a simple, reliable, and highly sensitive method with a potential use in biological systems, food, and drinks.

Published

2004

25. Immobilization of lactase from Kluyveromyces lactis greatly reduces the inhibition promoted by glucose. full hydrolysis of lactose in milk.

Author

Mateo C, Monti R, Pessela BC, Fuentes M, Torres R, Guisán JM, and Fernández-Lafuente R

Subjects

Animals, Enzyme Stability, Enzymes, Immobilized antagonists & inhibitors, Hydrolysis, Kinetics, Lactase antagonists & inhibitors, Enzyme Inhibitors metabolism, Enzymes, Immobilized metabolism, Glucose metabolism, Kluyveromyces enzymology, Lactase metabolism, Lactose metabolism, Milk metabolism

Abstract

The kinetic constants (Km, Vmax, and inhibition constants for the different products) of soluble and different immobilized preparations of beta-galactosidase from Kluyveromyces lactis were determined. For the soluble enzyme, the Km was 3.6 mM, while the competitive inhibition constant by galactose was 45 mM and the noncompetitive one by glucose was 758 mM. The immobilized preparations conserved similar values of Km and competitive inhibition, but in some instances much higher values for the noncompetitive inhibition constants were obtained. Thus, when glyoxyl or glutaraldehyde supports were used to immobilize the enzyme, the noncompetitive inhibition was greatly reduced (Ki approximately 15,000 and >40,000 mM, respectively), whereas when using sugar chains to immobilize the enzyme the behavior had an effect very similar to the soluble enzyme. These results presented a great practical relevance. While using the soluble enzyme or the enzyme immobilized via the sugar chain as biocatalysts in the hydrolysis of lactose in milk only around 90% of the substrate was hydrolyzed, by using of these the enzyme immobilized via the glyoxyl or the glutaraldehyde groups, more than 99% of the lactose in milk was hydrolyzed.

Published

2004

26. Reversible immobilization of glucoamylase by ionic adsorption on sepabeads coated with polyethyleneimine.

Author

Torres R, Pessela BC, Mateo C, Ortiz C, Fuentes M, Guisan JM, and Fernandez-Lafuente R

Subjects

Adsorption, Aspergillus niger enzymology, Cation Exchange Resins, Enzymes, Immobilized antagonists & inhibitors, Glucan 1,4-alpha-Glucosidase antagonists & inhibitors, Ions, Enzymes, Immobilized metabolism, Glucan 1,4-alpha-Glucosidase metabolism, Polyethyleneimine chemistry

Abstract

Glucoamylase (GA) from Aspergillus niger was immobilized via ionic adsorption onto DEAE-agarose, Q1A-Sepabeads, and Sepabeads EC-EP3 supports coated with polyethyleneimine (PEI). After optimization of the immobilization conditions (pH, polymer size), it was observed that the adsorption strength was much higher in PEI-Sepabeads than in Q1A-Sepabeads or DEAE-supports, requiring very high ionic strength to remove glucoamylase from the PEI-supports (e.g., 1 M NaCl at pH 5.5). Thermal stability and optimal temperature was marginally improved by this immobilization. Recovered activity depended on the substrate used, maltose or starch, except when very low loading was used. The optimization of the loading allowed the preparation of derivatives with 750 IU/g in the hydrolysis of starch, preserving a high percentage of immobilized activity (around 50%).

Published

2004

27. A new, mild cross-linking methodology to prepare cross-linked enzyme aggregates.

Author

Mateo C, Palomo JM, van Langen LM, van Rantwijk F, and Sheldon RA

Subjects

Binding Sites, Catalysis, Dextrans metabolism, Glutaral metabolism, Molecular Weight, Penicillin Amidase metabolism, Cross-Linking Reagents metabolism, Enzymes, Immobilized metabolism

Abstract

Cross-linked enzyme aggregates (CLEAs) were prepared from several enzymes (penicillin G acylase, hydroxynitrile lyase, alcohol dehydrogenase, and two different nitrilases) by precipitation and subsequent cross-linking using dextran polyaldehyde. In most cases, higher immobilization yields were obtained using the latter cross-linker as compared with the commonly used glutaraldehyde. Active site titration of penicillin acylase CLEAs showed that the higher activity originated from a significantly lower loss in active sites using dextran polyaldehyde as a cross-linking agent. It is proposed that macromolecular cross-linkers are too large to penetrate the protein active site and react with catalytically essential amino acid residues., (Copyright 2004 Wiley Periodicals, Inc.)

Published

2004

28. Novel bifunctional epoxy/thiol-reactive support to immobilize thiol containing proteins by the epoxy chemistry.

Author

Grazú V, Abian O, Mateo C, Batista-Viera F, Fernández-Lafuente R, and Guisán JM

Subjects

Dithiothreitol chemistry, Epoxy Compounds chemistry, Sulfhydryl Compounds chemistry, Enzymes, Immobilized

Abstract

In this manuscript, we present a new bifunctional support containing epoxide and thiol-reactive groups for its use in protein immobilization. In a first step, the proteins are reversibly immobilized by reaction of its thiol groups with the thiol-reactive groups of the support under mild experimental conditions (pH 7.0, 24 degrees C). Then, the remaining epoxides of the support can form irreversible bonds with nucleophile surface groups of the already immobilized protein in a rapid way. The partial derivatization of EP-Sepabeads (a commercial matrix containing 120 micromol epoxy groups/g drained support) was optimized, using dithiotreitol (DTT) as thiolating agent. It was possible to achieve a partial thiolation of the support proportional to the concentration of DTT used (3, 8, and 15 micromol SH groups/g wet support). The remaining epoxide content after the thiolation treatment was high (e.g., nearly 70% for the highest thiolation degree). High immobilization yields were obtained for the three model enzymes selected (60% for Penicillin G acylase, 65% and 100% for K. lactis and E. coli beta-galactosidase, respectively). In all cases, no significant immobilization onto an unmodified epoxy support was found, thus demonstrating that the first step of attachment takes place through thiol-disulfide exchange reactions. In the case of the bifunctional support, progressive formation of enzyme-support attachments involving the epoxy groups was showed by the irreversible covalent attachment of the proteins on the support. The promotion of this multipoint covalent immobilization required long incubation periods at basic pH values.

Published

2003

29. Enzymatic transformations. Immobilized A. niger epoxide hydrolase as a novel biocatalytic tool for repeated-batch hydrolytic kinetic resolution of epoxides.

Author

Mateo C, Archelas A, Fernandez-Lafuente R, Guisan JM, and Furstoss R

Subjects

Catalysis, Kinetics, Stereoisomerism, Aspergillus niger enzymology, Enzymes, Immobilized metabolism, Epoxide Hydrolases metabolism, Epoxy Compounds metabolism

Abstract

Studies aimed at immobilization of the Aspergillus niger epoxide hydrolase were performed. The use of conventional approaches, i.e. of commercially available supports and classical methodologies, only led to low stabilisation and unsatisfactory enzymatic activity recovery. Therefore, a new strategy based on the use of a "second generation" type of epoxy-activated supports allowing multi-point covalent immobilization, i.e. Eupergit C, partially modified with ethylene diamine (Eupergit C/EDA), and of an adequate experimental procedure was set up. This allowed us to prepare an immobilized biocatalyst with 70%, retention of the initial enzymatic activity and a stabilisation factor of about 30. Interestingly, this biocatalyst also led to a noticeable increase of the E value for the resolution of two test substrates, styrene oxide 1 and p-chlorostyrene oxide 2. This was improved from about 25 to 56 and from 40 to 100, respectively. A typical repeated batch experiment indicated that the thus immobilized enzyme could be re-used for over 12 cycles without any noticeable loss of enzymatic activity or change in enantioselectivity. This therefore opens the way for the use of an 'heterogeneous catalysis' methodology for achieving the preparation of various enantiopure epoxides via biocatalysed hydrolytic kinetic resolution.

Published

2003

30. Preparation of a stable biocatalyst of bovine liver catalase using immobilization and postimmobilization techniques.

Author

Betancor L, Hidalgo A, Fernández-Lorente G, Mateo C, Fernández-Lafuente R, and Guisan JM

Subjects

Animals, Catalysis, Cattle, Cross-Linking Reagents chemistry, Enzyme Activation, Enzyme Stability, Liver chemistry, Protein Conformation, Protein Denaturation, Protein Structure, Quaternary, Temperature, Catalase chemistry, Enzymes, Immobilized chemistry, Enzymes, Immobilized isolation & purification, Liver enzymology, Membranes, Artificial

Abstract

Bovine liver catalase was immobilized on different supports. The tetrameric nature of this enzyme was found to cause its rapid inactivation in diluted conditions due to subunit dissociation, a fact that may rule out its industrial use. Multi-subunit immobilization using highly activated glyoxyl agarose was not enough to involve all enzyme subunits. In fact, washing the derivative produced a strong decrease in the enzyme activity. Further cross-linking of previously immobilized enzyme with tailor-made dextran-aldehyde permitted the multimeric structure to be fully stabilized using either multisubunit preparations immobilized onto highly activated glyoxyl-agarose support or one subunit enzymes immobilized onto poorly activated glyoxyl-agarose. The highest stability of the final biocatalyst was observed using the multisubunit immobilized derivative cross-linked with dextran-aldehyde. The optimal derivative retained around 60% of the immobilized activity, did not release any enzyme subunits after boiling in the presence of SDS, and did not lose activity during washing, and its stability did not depend on the dilution. This derivative was used for 10 cycles in the destruction of 10 mM hydrogen peroxide without any decrease in the enzyme activity.

Published

2003

31. A novel heterofunctional epoxy-amino sepabeads for a new enzyme immobilization protocol: immobilization-stabilization of beta-galactosidase from Aspergillus oryzae.

Author

Torres R, Mateo C, Fernández-Lorente G, Ortiz C, Fuentes M, Palomo JM, Guisan JM, and Fernández-Lafuente R

Subjects

Amino Acids chemistry, Coated Materials, Biocompatible chemical synthesis, Coated Materials, Biocompatible chemistry, Enzyme Activation, Enzyme Stability, Microspheres, Aspergillus oryzae chemistry, Aspergillus oryzae enzymology, Enzymes, Immobilized biosynthesis, Enzymes, Immobilized chemistry, Epoxy Resins chemistry, Ethylenediamines chemistry, beta-Galactosidase biosynthesis, beta-Galactosidase chemistry

Abstract

The properties of a new and commercially available amino-epoxy support (amino-epoxy-Sepabeads) have been compared to conventional epoxy supports to immobilize enzymes, using the beta-galactosidase from Aspergillus oryzae as a model enzyme. The new support has a layer of epoxy groups over a layer of ethylenediamine that is covalently bound to the support. This support has both a great anionic exchanger strength and a high density of epoxy groups. Epoxy supports require the physical adsorption of the proteins onto the support before the covalent binding of the enzyme to the epoxy groups. Using conventional supports the immobilization rate is slow, because the adsorption is of hydrophobic nature, and immobilization must be performed using high ionic strength (over 0.5 M sodium phosphate) and a support with a fairly hydrophobic nature. Using the new support, immobilization may be performed at moderately low ionic strength, it occurs very rapidly, and it is not necessary to use a hydrophobic support. Therefore, this support should be specially recommended for immobilization of enzymes that cannot be submitted to high ionic strength. Also, both supports may be expected to yield different orientations of the proteins on the support, and that may result in some advantages in specific cases. For example, the model enzyme became almost fully inactivated when using the conventional support, while it exhibited an almost intact activity after immobilization on the new support. Furthermore, enzyme stability was significantly improved by the immobilization on this support (by more than a 12-fold factor), suggesting the promotion of some multipoint covalent attachment between the enzyme and the support (in fact the enzyme adsorbed on an equivalent cationic support without epoxy groups was even slightly less stable than the soluble enzyme).

Published

2003

32. Solid-phase handling of hydrophobins: immobilized hydrophobins as a new tool to study lipases.

Author

Palomo JM, Peñas MM, Fernández-Lorente G, Mateo C, Pisabarro AG, Fernández-Lafuente R, Ramírez L, and Guisán JM

Subjects

Candida enzymology, Enzymes, Immobilized chemistry, Lipase chemistry, Pseudomonas fluorescens enzymology, Enzymes, Immobilized metabolism, Fungal Proteins metabolism, Lipase metabolism

Abstract

Hydrophobins are fungal proteins that self-assemble spontaneously at hydrophilic-hydrophobic interfaces and change the polar nature of the surfaces to which they attach. This attribute can be used to introduce hydrophobic foci on the surface of hydrophilic supports where hydrophobins are attached by covalent binding. In this paper, we report the binding of Pleurotus ostreatus hydrophobins to a hydrophilic matrix (agarose) to construct a support for noncovalent immobilization and activation of lipases from Candida antarctica, Humicola lanuginosa, and Pseudomonas flourescens. Lipase immobilization on agarose-bound hydrophobins proceeded at very low ionic strength and resulted in increased lipase activity and stability. The enzyme could be desorbed from the support using moderate concentrations of Triton X-100, and its enantioselectivity was similar to that of lipases interfacially immobilized on conventional hydrophobic supports. These results suggest that lipase adsorption on hydrophobins follows an "interfacial activation" mechanism; immobilization on hydrophobins offers new possibilities for lipase study and modulation and reveals a new application for fungal hydrophobins.

Published

2003

33. One-step purification, covalent immobilization, and additional stabilization of a thermophilic poly-His-tagged beta-galactosidase from Thermus sp. strain T2 by using novel heterofunctional chelate-epoxy Sepabeads.

Author

Pessela BC, Mateo C, Carrascosa AV, Vian A, García JL, Rivas G, Alfonso C, Guisan JM, and Fernández-Lafuente R

Subjects

Chelating Agents, Chromatography, Affinity methods, Cloning, Molecular, Enzyme Stability, Enzymes, Immobilized metabolism, Epoxy Compounds, Escherichia coli enzymology, Kinetics, Metals, Recombinant Proteins chemistry, Recombinant Proteins isolation & purification, Recombinant Proteins metabolism, beta-Galactosidase isolation & purification, beta-Galactosidase metabolism, Enzymes, Immobilized chemistry, Thermus enzymology, beta-Galactosidase chemistry

Abstract

Using the poly-His-tagged-beta-galactosidase from Thermus sp. strain T2 overexpressed in Escherichia coli (MC1116) as a model enzyme, we have developed a strategy to purify and immobilize proteins in a single step, combining the excellent properties of epoxy groups for enzyme immobilization with the good performance of immobilized metal-chelate affinity chromatography for protein purification. The aforementioned enzyme could not be immobilized onto standard epoxy supports with good yields, and after purification and storage, it exhibited a strong trend to yield very large aggregates as shown by ultracentrifugation experiments. That preparation could not be immobilized in any support, very likely because the pores of the solid became clogged by the large aggregates. These novel epoxy-metal chelate heterofunctional supports contain a low concentration of Co(2+) chelated in IDA groups and a high density of epoxy groups. This enabled the selective adsorption of poly-His-tagged enzymes, and as this adsorption step is necessary for the covalent immobilization procedure, the selective covalent immobilization of the target enzyme could take place. This strategy allowed similar maximum loadings of the target enzyme using either pure or crude preparations of the enzyme. The enzyme derivative presented a very high activity at 70 degrees C (over 1000 IU in the hydrolysis of lactose) and very high stability and stabilization when compared to its soluble counterpart (activity remained unaltered after several days of incubation at 50 degrees C). In fact, this preparation was much more stable than when the same enzyme was immobilized onto standard epoxy Sepabeads.

Published

2003

34. Reversible immobilization of invertase on Sepabeads coated with polyethyleneimine: optimization of the biocatalyst's stability.

Author

Torres R, Mateo C, Fuentes M, Palomo JM, Ortiz C, Fernández-Lafuente R, Guisan JM, Tam A, and Daminati M

Subjects

Dimerization, Enzyme Stability, Enzymes, Immobilized metabolism, Glycoside Hydrolases metabolism, Hydrogen-Ion Concentration, Microspheres, Polyethyleneimine, Protein Conformation, Saccharomyces cerevisiae enzymology, Static Electricity, Temperature, beta-Fructofuranosidase, Enzymes, Immobilized chemistry, Glycoside Hydrolases chemistry

Abstract

Invertase from S. cerevisiae has been immobilized by ionic adsorption on Sepabeads fully coated with PEI. The enzyme was strongly adsorbed on the support (no desorption of the invertase was found under conditions in which all of the enzyme was released from conventional anionic exchanger supports (e.g., DEAE-agarose)). Nevertheless, the enzyme could still be desorbed after its inactivation, and new fresh enzyme could be adsorbed on the supports without detrimental effects on enzyme loading. This is a multimeric enzyme, its minimal oligomerization active state being the dimer, but under certain conditions of pH and concentration it may give larger multimers. Very interestingly, results suggested that the adsorption of the enzyme on this large and flexible polymeric bed was able to freeze some of the different oligomeric structures of the enzyme. Thus, we have found that the enzyme immobilized at certain pH values (pH 8.5) and high enzyme concentration, in which the main enzyme structure is the tetramer, was more stable than immobilized preparations produced in conditions under which oligomerization was not favorable (dimers at low enzyme concentration) or it was too high (e.g., hexamers-octamers at low pH value). The optimal enzyme preparation remained fully active after a 15-day incubation at 50 degrees C and pH 4.5 (conditions of standard industrial use) and presented an optimal temperature approximately 5 degrees C higher than that of soluble enzyme.

Published

2002

35. Epoxy sepabeads: a novel epoxy support for stabilization of industrial enzymes via very intense multipoint covalent attachment.

Author

Mateo C, Abian O, Fernández-Lorente G, Pedroche J, Fernández-Lafuente R, Guisan JM, Tam A, and Daminati M

Subjects

Enzyme Stability, Enzymes, Immobilized chemistry, Penicillin Amidase chemistry, Surface Properties, Enzymes, Immobilized metabolism, Epoxy Compounds chemistry, Penicillin Amidase metabolism

Abstract

Sepabeads-EP (a new epoxy support) has been utilized to immobilize-stabilize the enzyme penicillin G acylase (PGA) via multipoint covalent attachment. These supports are very robust and suitable for industrial purposes. Also, the internal geometry of the support is composed by cylindrical pores surrounded by the convex surfaces (this offers a good geometrical congruence for reaction with the enzyme), and it has a very high superficial density of epoxy groups (around 100 micromol/mL). These features should permit a very intense enzyme-support interaction. However, the final stability of the immobilized enzyme is strictly dependent on the immobilization protocol. By using conventional immobilization protocols (neutral pH values, nonblockage of the support) the stability of the immobilized enzyme was quite similar to that achieved using Eupergit C to immobilize the PGA. However, when using a more sophisticated three-step immobilization/stabilization/blockage procedure, the Sepabeads derivative was hundreds-fold more stable than Eupergit C derivatives. The protocol used was as follows: (i) the enzyme was first covalently immobilized under very mild experimental conditions (e.g., pH 7.0 and 20 degrees C); (ii) the already immobilized enzyme was further incubated under more drastic conditions (higher pH values, long incubation periods, etc.) in order to "facilitate" the formation of new covalent linkages between the immobilized enzyme molecule and the support; (iii) the remaining epoxy groups of the support were blocked with very hydrophilic compounds to stop any additional interaction between the enzyme and the support. This third point was found to be critical for obtaining very stable enzymes: derivatives blocked with mercaptoethanol were much less stable than derivatives blocked with glycine or other amino acids. This was attributed to the better masking of the hydrophobicity of the support by the amino acids (having two charges).

Published

2002

36. Modulation of penicillin acylase properties via immobilization techniques: one-pot chemoenzymatic synthesis of Cephamandole from Cephalosporin C.

Author

Terreni M, Pagani G, Ubiali D, Fernández-Lafuente R, Mateo C, and Guisán JM

Subjects

Cefamandole metabolism, Cephalosporins metabolism, Enzymes, Immobilized metabolism, Escherichia coli enzymology, Sepharose chemistry, Biochemistry methods, Cefamandole chemical synthesis, Cephalosporins chemistry, Enzymes, Immobilized chemistry, Penicillin Amidase chemistry, Penicillin Amidase metabolism

Abstract

The modulation of penicillin G acylase (PGA) properties via immobilization techniques has been performed studying the acylation of 7-aminocephalosporanic acid with R-mandelic acid methyl ester. PGA from Escherichia coli, immobilized onto agarose activated with glycidol (glyoxyl-agarose), has been used for the design of a novel one-pot synthesis of Cephamandole in aqueous medium and without isolation of intermediates, through three consecutive biotransformations catalyzed by D-amino acid oxidase, glutaryl acylase and PGA.

Published

2001

37. Multifunctional epoxy supports: a new tool to improve the covalent immobilization of proteins. The promotion of physical adsorptions of proteins on the supports before their covalent linkage.

Author

Mateo C, Fernández-Lorente G, Abian O, Fernández-Lafuente R, and Guisán JM

Subjects

Acetobacter chemistry, Adsorption, Amines chemistry, Bacterial Proteins chemistry, Chelating Agents, Copper, Escherichia coli chemistry, Imino Acids, Indicators and Reagents, Lipase chemistry, Penicillin Amidase chemistry, Polymers, beta-Galactosidase chemistry, Enzymes, Immobilized chemistry, Epoxy Compounds chemistry, Proteins chemistry

Abstract

Multifunctional supports containing epoxy groups are here proposed as a second generation of activated supports for covalent immobilization of enzymes following the epoxy chemistry on any type of support (hydrophobic or hydrophilic ones) under very mild experimental conditions (e.g., low ionic strength, neutral pH values, and low temperatures). These multifunctional supports have been easily prepared by modifying a small fraction (10-20%) of the epoxy groups contained in commercial epoxy supports. In this way, additional groups that were able to physically adsorb proteins (e.g., cationic or anionic groups, metal chelate, phenyl boronate) are generated on the support surface. The covalent immobilization of proteins on these supports proceeds via their initial physical adsorption on the supports (via different structural features). Then, "intramolecular" covalent linkages between some nucleophilic groups of the adsorbed enzyme (e.g., amino, thiol, or hydroxy groups) and the dense layer of nearby epoxy groups on the support are established. This two-step covalent immobilization dramatically improves the very low reactivity of epoxy groups toward nonadsorbed proteins. In this way, all other relevant practical advantages of epoxy groups for protein immobilization (their high stability and their ability to form very strong linkages with several nucleophilic enzyme residues with minimal chemical modification) can be an object of universal exploitation. The use of these new multifunctional supports exhibits important advantages regarding immobilization of enzymes previously adsorbed on hydrophobic homofunctional epoxy supports: (i) hydrophilic supports can also be used for immobilization of industrial enzymes; (ii) immobilization can also be carried out at low ionic strength; (iii) every protein contained in crude extracts from Escherichia coli and Acetobacter turbidans can be immobilized by sequentially using a set of different supports; (iv) in most cases, each enzyme has been immobilized on different supports, orientated through different structural features and very likely involving different areas of its surface. For example, three industrial enzymes (penicillin G acylase, lipase, and beta-galactosidase) could be immobilized through different strategies yielding immobilized derivatives with very different activities. The best derivatives preserved 75-100% of activity corresponding to the soluble enzymes used for immobilization, while in some cases a particular immobilization protocol promoted the full inactivation of the enzyme.

Published

2000

38. Reversible enzyme immobilization via a very strong and nondistorting ionic adsorption on support-polyethylenimine composites.

Author

Mateo C, Abian O, Fernandez-Lafuente R, and Guisan JM

Subjects

Adsorption, Anion Exchange Resins, Biotechnology methods, Enzymes, Immobilized, Polyethyleneimine

Abstract

New tailor-made anionic exchange resins have been prepared, based on films of large polyethylenimine polymers (e.g., MW 25,000) completely coating, via covalent immobilization, the surface of different porous supports (agarose, silica, polymeric resins). Most proteins contained in crude extracts from different sources have been very strongly adsorbed on them. Ionic exchange properties of such composites strongly depend on the size of polyethylenimine polymers as well as on the exact conditions of the covalent coating of the solids with the polymer. On the contrary, similar coating protocols yield similar matrices by using different porous supports as starting material. For example, 77% of all proteins contained in crude extracts from Escherichia coli were adsorbed, at low ionic strength, on the best matrices, and less than 15% of the adsorbed proteins were eluted from the support in the presence of 0.3 M NaCl. Under these conditions, 100% of the adsorbed proteins were eluted from conventional DEAE supports. Such polyethylenimine-support composites were also very suitable to perform very strong and nondistorting reversible immobilization of industrial enzymes. For example, lipase from Candida rugosa (CRL), beta-galactosidase from Aspergillus oryzae and D-amino acid oxidase (DAAO) from Rhodotorula gracilis, were adsorbed on such matrices in a few minutes at pH 7.0 and 4 degrees C. Immobilized enzymes preserved 100% of catalytic activity and remained fully immobilized in 0.2 M NaCl. In addition to that, CRL and DAAO were highly stabilized upon immobilization. Stabilization of DAAO, a dimeric enzyme, seems to be due to the involvement of both enzyme subunits in the ionic adsorption., (Copyright 2000 John Wiley & Sons, Inc.)

Published

2000